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From Quantum Entanglement to Spatiotemporal Distance1
Alyssa Ney
September 9, 2020
1. Introduction
Within the field of quantum gravity, there is an influential research program developing the
connection between quantum entanglement and spatiotemporal distance. Quantum information
theory gives us highly refined tools for quantifying quantum entanglement. A common measure
is the von Neumann entropy S, which can be seen as a quantum analog of the Shannon entropy
(Nielsen and Chuang 2016, Preskill 1998). For a state with density matrix 𝜌,
(1.1) 𝑆(𝜌) = −𝑡𝑟(𝜌𝑙𝑜𝑔𝜌).
The von Neumann entropy gives one a measure of how entangled a system is. So, for example, if
we consider a bipartite system 𝜎!", we may ask how entangled are its parts, 𝜎! and 𝜎". In this
case, we can refer to 𝑆(𝜌!) and 𝑆(𝜌") as the parts’ entanglement entropies, where 𝜌! and 𝜌" are
the reduced density matrices of the system’s parts. Suppose 𝜌!" is a pure state. The von
Neumann entropy for any pure state is identically zero. If the joint state of the system is a
product state so that 𝜌!" = 𝜌!⨂𝜌", then the entanglement entropy for either part, 𝑆(𝜌!) or
𝑆(𝜌") will also be zero. On the other hand, for an entangled system, the entanglement entropy of
the parts will not be zero. Indeed, depending on the degrees of freedom of the system, there will
be a maximum value of the entanglement entropy associated with the maximally entangled state.
For a system of qubits, this will be the value associated with the Bell states, 𝜓!" =
#√%(|01⟩ ± |10⟩) and 𝜓!" =
#√%(|00⟩ ± |11⟩).
1 Thanks to Steve Carlip, Veronika Hubeny, Nick Huggett, and an anonymous referee for comments and discussions that substantially improved this paper.
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Through a series of well-confirmed results, it has been shown how these facts about the
entanglement entropy of component systems may be connected to facts about spatiotemporal
distance.2 Physicists are seeing these results as yielding promising methods for better
understanding the emergence of (the dynamical) spacetime (of general relativity) from more
fundamental quantum theories, and moreover, as promising for the development of a
nonperturbative theory of quantum gravity. These results appear to be part of a more general
convergence forming from several different approaches to quantum gravity (string theory, spin
foams, causal sets) around the idea that spacetime, dynamical spacetime of the kind found in
general relativity, is an emergent phenomenon, a phenomenon that arises in some sense or other
from a more fundamental, non-gravitational description (Carlip 2012, Huggett and Wüthrich
2013, Oriti forthcoming). However, to what extent does the case for the entanglement entropy-
distance link provide evidence that spacetime structure is nonfundamental and emergent from
nongravitational degrees of freedom? I will show that a closer look at the results lends support
only to a weaker conclusion, that the facts about quantum entanglement are constrained by facts
about spatiotemporal distance, and not that they are the basis from which facts about
spatiotemporal distance emerge.
2. Constructing the Metric from Entanglement Entropy in the AdS/CFT Context
2 We may note, in anticipation of this fact that entanglement entropy will be connected with spatiotemporal distance, that this quantity has certain features that make it apt to serve as a distance relation itself. In particular, it satisfies the triangle inequality: For a joint state 𝜌!" ,𝑆(𝜌!") ≥ |𝑆(𝜌!) − 𝑆(𝜌")| (Nielsen and Chuang 2016, pp. 515-516). On the other hand, since, for example, 𝑆(𝜌!") can equal zero even when 𝜌! ≠ 𝜌", the entanglement entropy has other features that make it seem unlike a distance relation.
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Let’s start by looking at results connecting facts about the spacetime metric with facts about
quantum entanglement that have been motivated from within the string theory paradigm. These
follow first on Maldacena’s (1997) discovery of the AdS/CFT correspondence. Maldacena shows
how one can establish a holographic correspondence between pairs of theories.3 For, example
one may consider first a gravitational theory, a string theory on anti-de Sitter (AdS) spacetime in
d+1 dimensions; and next a theory without gravitational degrees of freedom, a conformal field
theory, a type of quantum field theory with a kind of scaling symmetry (CFT), defined on a flat
spacetime in d dimensions.
Figure 1: AdS/CFT Correspondence
In this model, one may view the AdS description as defining a bulk spacetime for which the CFT
lies on its boundary. Maldacena shows how one can translate back and forth between the
description of the d+1-dimensional spacetime in the bulk and the D-dimensional spacetime on its
boundary. This work has been extremely influential and so it is a good place to start to look for
3 The explicit connection with holography was made in Witten (1998).
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mainstream arguments on the link between quantum features and spacetime structure. Even
though we don’t ourselves inhabit an AdS spacetime, this correspondence shows us how one
might, for at least one case, derive facts about a curved spacetime, and hence gravity, from a
quantum theory without it.
I want to look at a particular line of research that has started within the AdS/CFT context,
work that aims to derive facts about the AdS metric using particular facts about the CFT on the
boundary, in particular, facts about the entanglement entropy of particular states living on the
boundary.4 In 2006, Ryu and Takayanagi asked us to consider the following. First, take a CFT
boundary and divide it into two regions, A and its complement, �̅�.
Figure 2: Ryu-Takayanagi Cut
We may then consider the reduced density matrices 𝜌!, that describes the state on region A, and
𝜌!̅, that describes the state on the complement region �̅�.Given these density matrices, we can
4 Rickles (2013), Teh (2013), Dieks et. al. (2015), Read (2016), De Haro (2017, 2020), Butterfield (forthcoming), Huggett and Wüthrich (forthcoming) are prior philosophical works on the AdS/CFT correspondence. Jaksland (forthcoming) discusses the Ryu-Takayanagi conjecture.
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then compute their entanglement entropy. Assuming the total boundary region is in a pure state,
𝑆(𝜌!) = 𝑆(𝜌!̅). Now consider the minimal surface running through the AdS bulk that connects
the two edges dividing region A from its complement. Call this surface 𝛾!.
Figure 3: Minimal Surface
The Ryu-Takayanagi conjecture is that a particular relationship exists between the area (or in the
d=1 case, length) of 𝛾! and the entanglement entropy of the region on the boundary A:
(2.1) 𝑆(𝜌!) = '()'+,-!./"
($%&) ,
where GNd+1 is Newton’s constant for the relevant d+1-dimensional space.5 Those familiar with
work on black hole thermodynamics will immediately recognize that this relationship has the
same form as the Bekenstein-Hawking formula that relates the entropy of a black hole to the area
of its event horizon (Bekenstein 1973, Hawking 1975):
5 This is expressed using units where ℏ = 𝑐 = 𝑘" = 1.
6
(2.2) 𝑆"0 ='()'+,12))3)412+(56+4
./.
This is something we will come back to. Ryu and Takayanagi motivate their conjecture by
appeal to this earlier work on black hole entropy, and in particular, the explanation of why this
formula holds developed by Sorkin and his collaborators (Sorkin 1983, Bombelli et. al. 1986).
We will discuss below how Ryu and Takayanagi establish their conjecture. For now, it is
just worth noting how influential this work has been in motivating a research program in
quantum gravity, working within the AdS/CFT context, for seeing the connection between facts
about quantum entanglement (entanglement entropy) in a quantum field theory without
gravitational degrees of freedom, and facts about the metric in a curved (AdS) spacetime. To
begin, Hubeny, Rangamani, and Takayanagi (2007) generalized the result from one about a static
region of the AdS spacetime to more general regions, providing a covariant account of AdS
distances in quantum information theoretic terms. Later work asked whether it possible to
recover more of the AdS metric from the entanglement properties of regions on the boundary,
beyond the area of the minimal surfaces 𝛾!. That is, how far can we succeed in “bulk
reconstruction,” i.e. in gaining an understanding of “how these degrees of freedom, which are
well-understood from the perspective of nongravitational quantum field theory, reorganize
themselves (in an appropriate limit) into a manifestly local gravitational theory” (Bao et. al 2019,
p. 1). Indeed for a complete reconstruction, we would want to not only to extract the metric of
the bulk, but also the dynamics.
The work on “hole-ography” of, for example, Balasubramanian et. al. (2014), Headrick
et. al, (2014) and Myers et. al. (2014) aims to construct the metrical properties of closed surfaces
embedded in the AdS space from entanglement entropies on the boundary field theory. The
strategy can be (loosely) explicated as follows. Take a closed surface in the AdS bulk.
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Figure 4: Closed Surface in the AdS Bulk
Now find geodesics k that are tangent to each region on that closed surface and extend them out
to the CFT boundary to get a boundary region Ik.
Figure 5: Tangent Curve Extended to the CFT Boundary
The idea then is to argue that one can recover the surface’s area in terms of the entanglement
entropies on the boundary using:
(2.3) 𝐸 = ∑ [𝑆(𝐼7) − 𝑆(𝐼7 ∩ 𝐼78#)]479# ,
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where E is what Myers et. al. refer to as the differential entropy. The area of the surface is
identified with the limit of this quantity as n®¥.6
These developments lead Keeler and her collaborators to argue that entanglement
entropies on the boundary are sufficient to uniquely fix the metric (up to diffeomorphism)
everywhere in the neighborhood of the extremal surfaces (Bao et. al. 2019). Although for the
generic case, one will not be able to rule out the existence of “entanglement shadows” in the AdS
bulk, regions where the metric is left undetermined by the entropy of boundary regions, perhaps
because there are regions which extremal surfaces can’t cross due to singularities (cf. Headrick
et. al. 2014, p. 38), large steps have already been taken to capture a lot of information about the
AdS metric in terms of quantum entanglement on the CFT boundary. Explicit reconstructions
have already been successful for bulk spacetimes with large-scale symmetries (Rangamani and
Takayanagi 2017).
3. The Entanglement Entropy-Distance Link Beyond AdS/CFT: Area Laws
As noted, our universe doesn’t have an AdS geometry, and so one might ask whether these
results are confined to the AdS/CFT context, or whether we may have justification for seeing a
connection between entanglement entropy of the parts of a system and distance in the more
general case. Let us back up and reframe a bit what we are after. So far, what we are seeing is the
6 Differential entropy is one of many entanglement measures that may be used to probe the area of such a bulk surface. Hubeny (2014) argues that it has several limitations. In particular, as Myers et. al. (2014) acknowledge, the original proposal is only well-defined for three-dimensional, pure AdS geometries, and only there where the bulk surface is not too “wiggly.” Myers et. al. modify the proposal to apply to more generic spacetimes, however Hubeny stresses that even the revised measures are defined only on static geometries. Her (2014) paper proposes a more robust measure: the covariant residual entropy. This is inspired by the earlier discussion of residual entropy in Balasubramian et. al. (2012).
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establishment of a series of area laws. Although in classical thermodynamics we are familiar
with the idea that entropy is an extensive quantity, scaling with volume, this is not so for the
cases we have been considering. In the case of black hole thermodynamics and the Ryu-
Takayanagi conjecture, (Bekenstein-Hawking or entanglement) entropies scale with area. And
this is what allows us to relate facts about entanglement entropy to facts about the metric.
The work we have just discussed argues for a direct correspondence between the
entanglement entropy of a CFT state A on the boundary and the area of surfaces through the AdS
bulk separating A from its complement. We should probe whether this connection between the
entanglement entropy of a region A and the area of the surface separating it from its complement
may be generalized from the AdS/CFT context to more general quantum systems. Indeed, there
are indications that area laws may hold more generally outside of the AdS/CFT context, and thus
there is a research program devoted to finding the conditions under which they hold. Again, this
is inspired by the Bekenstein-Hawking law for black hole entropy.
Although it is familiar from the consideration of Bell states in quantum mechanics that
quantum entanglement/correlations may persist over indefinitely long spatial distances,
interactions in quantum many body systems are typically local. That is, subsystems typically
interact over short distances with only a finite number of neighboring subsystems. There is an
intuition that interactions are short-range because these correlations are enacted through the
interface surfaces7 between regions. An area law analogous to what we’ve already seen provides
support for this intuition.
7 I use ‘interface surface’ here to make a distinction with the ‘boundary surface’ in the AdS/CFT context. What we discuss here as the interface surface corresponds to the black hole’s event horizon or Ryu and Takayanagi’s minimal extremal surface.
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In a survey article, Eisert et. al. (2010) develop the case for area laws by illustration with
systems representable as a lattice, in particular one-dimensional systems where the entire system
may be represented as a chain of quantum systems L, and we focus on the entanglement entropy
of a part of this chain, e.g., the block I consisting of its first n members: {1,…,n}. However, it
may be shown.8
For such a one-dimensional chain, the boundary is very simple. The boundary is one or
two parts of the block, depending on the boundary conditions imposed. And so, we obtain an
area law for the entanglement entropy just in case 𝑆(𝜌:) is independent of the block size and
instead is proportional to 1.
(3.1) 𝑆(𝜌:) = 𝑂(1)
Eisert et. al. emphasize that their claim is not that area laws always hold for many body quantum
systems. Rather, one fact determining whether or not an area law holds is whether the system is
at a quantum critical point or not. For systems near criticality, the entanglement varies with the
length of the chain. And so, what we have is not an area law, but a volume law. This is not
surprising given what is known about the breakdown of locality in critical systems in
thermodynamics. In what follows, I summarize the argument, eliding most of the technical
details.
Consider a bosonic harmonic chain. In this case, the elements of the chain are modeled as
discrete versions of complex Klein-Gordon fields, that is, as spinless particles with charge. We
write down a Hamiltonian for this system in terms of the canonical operators x and p, and system
8 It is worth noting that the notion of area here is not quite the same as in the case of the Ryu-Takayanagi area law. The area in question here is that of the boundary between the two subsystems. In the latter case, it is the area of the dual bulk surface that ends on the boundary between the two entangled subsystems.
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operators X and P which describe the coupling structure. It turns out that even in such one-
dimensional systems, simple though they are, the entanglement entropy is quite difficult to
compute. However, there is another entanglement measure, the logarithmic negativity EN, that is
more tractable and which provides an upper bound for the entanglement entropy (at least for pure
states).
Following Eisert et. al., consider the simplest case where the chain L is bisected
symmetrically into two parts. We will assume the Hamiltonian describes parts of the system as
only able to directly interact with their nearest neighbors, so interactions are local. Here we have
a gapped system, one in which there are discrete energy gaps above the ground state that depend
on the coupling strength. In this case, Audenart et al. (2002) proved that:
(3.2) 𝑆(𝜌:) ≤ 𝐸;(𝜌, 𝐼) =#%𝑙𝑜𝑔 G ‖=‖&/)
>*+,&)- (=)
H,
where ‖𝑋‖ is the norm of the system operator X. This was the first rigorous area law for a
quantum lattice system. As one can see, the upper bound for entanglement entropy does not
depend on the size of the subsystem I. It is thus independent of the block size. This result has
been extended to simple higher-dimensional systems, e.g. for quasi-free systems of bosons or
fermions arranged on a lattice. For these systems, unlike for the one-dimensional case, the
boundary between subsystems is nontrivial. Again, one can calculate the logarithmic negativity
using system operators to find that the entanglement entropy scales with the boundary area.
Thus, Eisert et. al. (2010) draw from this work the conclusion that under the assumption of local
interactions, entanglement tracks the area of the surface separating the two subsystems. As they
put it, describing the import of (3.2):
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This result suggested that the locality of the interaction in the gapped model is inherited
by the locality of entanglement, a picture that was also confirmed in more generality.
(2010, p. 5)
In the case of criticality, just as for thermal systems, we lose the locality of interactions, and so
the assumptions used for deriving an area law fail. Entanglement entropy, in such cases, scales
with volume, as we would otherwise expect by analogy with the thermal entropy.
More recent work by Cao et. al. (2017) builds on these proofs of area laws using them
(again, outside of the AdS/CFT context) to argue that we can see the spacetime metric as
emerging from facts about entanglement entropy. Or, more accurately, Cao et. al. (2017) use the
quantum analog of the mutual information, I(A:B), which is defined in terms of the entanglement
entropy, and link this with facts about spatial distance:
(3.3) 𝐼(𝐴: 𝐵) ≡ 𝑆(𝜌!) + 𝑆(𝜌") − 𝑆(𝜌!") (Nielsen and Chuang 2016, p. 514).
The spacetime metric for Cao et. al. emerges from relations of mutual information between parts
of the total quantum state in Hilbert space. Eliding the details, we can just note that again, the
inference isn’t direct, but mediated by a claim about local interactions:
(2017, p. 4, my emphasis)
So again, for Cao et. al., it is in the assumption of a local field theory that the relevant area laws
obtain. We will return to this locality assumption shortly.
4. From Correspondence to Emergence?
The work described so far is very suggestive and, even if this is not always explicit as it is in the
work of Cao et. al., the establishment of such links between entanglement measures and metrical
features has held out the promise for many that one can see spacetime as emerging from facts
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about entanglement entropy. We certainly have, in these several cases, a bridge that can take us,
in certain well-defined contexts, back and forth between entanglement facts and facts about
spatiotemporal distance or area. But is there reason to see the one set of facts as emerging from
the other?9
Rickles (2013), Teh (2013), and Crowther (2014), in earlier discussions of the AdS/CFT
correspondence, have warned us to be cautious before moving from the existence of such a
duality or bridge, to a claim of emergence. And this is important: although the work we have
discussed may enable us the ability to move back and forth between two theoretical frameworks,
this is compatible with the holding of several possible inter-theoretic relationships:
1) Facts about the metric emerge from fundamental facts about entanglement entropy.
2) Facts about the entanglement entropy emerge from fundamental facts about the
metric.
3) Facts about the metric and entanglement entropy are equally fundamental.
4) Facts about the metric and entanglement entropy are neither fundamental, but both
emerge from some more fundamental, as yet undiscovered, framework.10
Following Teh, we must recognize that, before we can be justified in adopting a claim of
emergence (of facts in theory B from facts in theory A), we must establish that the A-facts are
9 As is standard in this literature, I will continue to use the language of emergence. But for these purposes, I could just as easily have framed the discussion in terms of whether we should see there being a reductive link, whether the facts about spacetime metric are reducible to facts about quantum entanglement. The central question is whether we should view the spatiotemporal facts not merely as derivable from facts about quantum entanglement, but whether we should view the spatiotemporal facts as arising from the facts about quantum entanglement, whether the facts about quantum entanglement provide the explanation of in virtue of what the spatiotemporal facts obtain. 10 This is the alternative both Rickles (2013) and Crowther (2014) express sympathy for when discussing the AdS/CFT correspondence.
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more fundamental, that they provide the explanation of in virtue of what the B-facts arise. Teh
(2013) acknowledges that in the AdS/CFT context, often, because it is easier to define the
quantum field theory than the gravity theory, there is reason to view the CFT as more
fundamental (cf. Horowitz 2005). But on the other hand, others are sympathetic to the possibility
that the AdS and CFT theories both emerge from some more fundamental theory (Teh 2013, p.
309).
Another issue that needs to be considered that is relevant to the question of emergence
concerns whether it is reasonable to believe the AdS/CFT correspondence, and in particular the
connection between entanglement entropies and spacetime quantities, is exact. Dieks et. al.
(2015, p. 208) note that although the AdS/CFT duality is often treated as an exact
correspondence, it is not clear whether this is actually so.11 If it is not exact, then experiments
could, in principle, decide the question of which of the two theories is the more fundamental and
settle a question of emergence. In the case in which it turns out the correspondence is exact,
Dieks et. al. are more skeptical that what we have is a situation in which either theory is more
fundamental: “in this case that the two theories completely agree on everything that is physically
meaningful, the two sides of the duality should be taken as different representations of one and
the same physical theory” (2015, p. 209).
Today, there is no established consensus on whether one side of the AdS/CFT duality is
more fundamental, or indeed whether neither is more fundamental than the other. And so, I
argue, we shouldn’t be basing a judgment of which of (1) - (4) is correct on what is the scientific
consensus about AdS/CFT. Moreover, some have argued that even if it is reasonable to think the
11 Harlow (2020) argues that this is confused, and that the AdS/CFT duality is exact. What is not exact, Harlow notes, is the relationship between the facts on either side of this duality and facts in some low-energy effective gravitational field theory.
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AdS/CFT correspondence supports a claim of emergence of spacetime from a more fundamental
quantum theory, it doesn’t itself explain how dynamical spacetime might emerge from a quantum
field theory on flat spacetime (c.f. Van Raamsdonk 2010). It is precisely here that concepts from
quantum information theory are supposed to come to the rescue. The connection with quantum
information theory may provide insights on which of (1) - (4) best describes the metaphysical
structure of our world, insights that may generalize beyond the AdS/CFT context.
5. Gluing With Entanglement?
As just mentioned, Van Raamsdonk (2010) notes that just from the AdS/CFT correspondence
alone, we can’t see how dynamical spacetime emerges from a nongravitational quantum field
theory. However, he believes that if one appeals to quantum information theoretic facts about
entanglement measures, then it can be made clear how what we have is a case of emergence. His
argument works by considering two cases. The first involves a set of disconnected AdS
spacetimes that we can then regard as connected by virtue of the entanglement relations in their
dual CFTs. The second case involves a single vacuum CFT in which we gradually remove the
entanglement between its component degrees of freedom. As this happens, we can see the
corresponding regions in the dual AdS spacetime as becoming pushed away from each other
until, when their mutual information goes to zero, the distance between them becomes infinite,
and they effectively pinch apart.
These cases are extremely suggestive, suggestive of the idea that there is a genuine
explanatory connection between the metrical features of an AdS spacetime and the entanglement
entropies of its dual quantum field theory. And especially in Van Raamsdonk’s discussion of the
first case, we see a good reason to think that there isn’t merely a correlation between the two
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theories, but that one set of facts is arising because of the other. However, as I will explain, it is
not clear to me that these cases are illustrating emergence as in option (1) of the previous section.
Let’s begin with the second case first, as it’s simpler, consisting of just one CFT and its
dual global AdS spacetime. Here, Van Raamsdonk’s discussion of the case provides a
fascinating picture of how the entanglement of degrees of freedom in a CFT track distance in its
holographic dual.
Figure 6: Minimal Surface Variation
Consider a point 𝑥! located on the edge of the bulk near the midpoint of region A on the
boundary, and another point 𝑥!̅ located on the other edge of the bulk near the midpoint of region
�̅�. What we see is that as the entanglement between region A and its complement is decreased,
the area of the region through the bulk AdS spacetime separating A from �̅�, what we earlier
denoted 𝛾!, decreases, and the distance between points 𝑥! and 𝑥!̅ increases. Eventually as
𝑆(𝜌!) → 0, 𝑥! and 𝑥!̅ pinch off from one another altogether.
So Van Raamsdonk’s second case illustrates the existence of a correlation between
entanglement entropy and distance. Indeed this correlation is a natural one given that as the
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entanglement entropy decreases, the mutual information 𝐼(𝐴: �̅�) also decreases, and (as Cao et.
al. 2007 also note) the mutual information has several features (positivity, symmetry, the obeying
of a triangle inequality) that make it particularly apt to be tracking distance relations. But what
reason is there to think this correlation is due to the emergence of the facts about distance from
the facts about entanglement? Van Raamsdonk’s case for the correlation and corresponding
images comes simply from an appeal to the Ryu-Takayanagi conjecture (2010, p. 3). And so, to
evaluate whether this connection comes from the fact that the spatiotemporal relations are
emerging from entanglement on the boundary (in support of my Option (1)), we must go back to
see what justifies the Ryu-Takayanagi area law in the first place.
We will return to that momentarily, but first let us consider Van Raamsdonk’s first case
in which we see a pair of disconnected AdS spacetimes becoming spatiotemporally connected,
“glued,” using quantum entanglement. First, Van Raamsdonk asks us to consider a pair of CFTs,
which we may call CFT1 and CFT2, each defined on S3 x R. In a product state, their combined
quantum state may be written as a tensor product, 𝜌!" = 𝜌!⨂𝜌". In this case, there is no
entanglement between the degrees of freedom of the two CFTs. And so their individual
entanglement entropies are identically zero. Here, CFT1 and CFT2 describe two separable
systems, and so, Van Raamsdonk argues (p. 1), the dual AdS spacetimes, AdS1 and AdS2 are
therefore disconnected.12
However, what if we take two such unentangled CFTs and combine them into a quantum
superposition? Van Raamsdonk asks us to consider the following superposition of product states:
12 One might already question this inference, at least insofar as it is supposed to generalize beyond the case of AdS/CFT, where we may assume each CFT gives a complete description of an AdS spacetime. Outside of the AdS/CFT context, we have no problem conceiving separable states of quantum systems where the component states 𝜌!and 𝜌" inhabit a common spacetime.
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(5.1) |𝜓⟩ = ∑ 𝑒./0+)5 |𝐸5⟩⨂|𝐸5⟩
This state, the Hawking-Hartle state, has been shown by Maldacena (2003) to correspond to a
classically connected spacetime, the eternal AdS black hole spacetime, which can be represented
by the following Penrose diagram:
Figure 7: Eternal AdS Black Hole Spacetime
Here, diagonal lines represent the light cone structure. Regions I and II correspond to the duals of
the reduced states for CFT1 and CFT2 respectively. Jagged lines represent the past and future
singularities.
Van Raamsdonk concludes how remarkable it is that such a complicated quantum state
can give rise to a spacetime with such a simple geometric description in classical terms:
… we have a remarkable conclusion: the state |𝜓⟩ which clearly represented a quantum
superposition of disconnected spacetimes may also be identified with a classically
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connected spacetime. In this example, classical connectivity arises by entangling the
degrees of freedom in the two components. (2010, p. 2)
But is this the correct order of explanation? In the eternal AdS black hole spacetime, the causal
futures of the two asymptotic regions AdS1 and AdS2 intersect past the event horizon. This is
their joint causal future, Region IV. As Van Raamsdonk notes, it follows from the AdS/CFT
correspondence that if we take a measurement on a state described by CFT1, the dual of the result
of that measurement will eventually enter region IV. This is the causal future of the dual to
CFT2. This suggests that measurement of CFT1 affects the state of CFT2, and supports the claim
that the two are entangled. Thus, it seems it is the spatiotemporal connection between AdS1 and
AdS2 that partially grounds the entanglement between the dual CFT1 and CFT2. But if this is
correct, then Van Raamsdonk’s discussion of the eternal AdS black hole seems most suggestive
of the idea that the order of explanation goes in the opposite direction than what he wants. It is
the spacetime structure that explains why it is that the measurement in the dual CFT1 has an
effect on the measurement in the dual CFT2, and so explains the entanglement of the two
component states. If this is right, then it is not that the quantum facts emerge from the geometric
facts, but rather that the latter constrains (and so helps to explain) the former.
Return to the four metaphysical options presented in Section 4.
1) Facts about the metric emerge from fundamental facts about entanglement entropy.
2) Facts about the entanglement entropy emerge from fundamental facts about the
metric.
3) Facts about the metric and entanglement entropy are equally fundamental.
4) Facts about the metric and entanglement entropy are neither fundamental, but both
emerge from some more fundamental, as yet undiscovered, framework.
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My claim is that Van Raamsdonk’s first case does not support Option (1) over its rivals, even if
it does support the existence of an explanatory connection between facts about entanglement
entropy and facts about the metric. The explanation of the entanglement relations in this case
presupposes facts about the metric.
6. Back to Ryu-Takayanagi and Black Hole Thermodynamics
Let’s try to seek out arguments for the emergence claim that are more promising by returning to
the Ryu-Takayanagi conjecture and seeing in the first place why this conjecture turns out to
work.
Recall again that Ryu and Takayanagi propose the following area law:
(6.1) 𝑆(𝜌!) = '()'+,-!./"
($%&) ,
where GNd+1 is Newton’s constant for the relevant D+1-dimensional space. It’s easiest to
understand the case for this area law in the context of a specific physical scenario. Let’s consider
the simplest case of d=2. Here we are considering an AdS3 gravity theory that is dual to a 1+1-
dimensional CFT. For an AdS3 spacetime with radius of curvature R, the dual CFT has central
charge c = 3R/2GN(3).
Now note that the metric of the AdS3 spacetime is:
(6.2) ds2 = R2(-coshr2dt2 + dr2 +sinhr2dθ2)
The proper distances diverge as r goes to infinity. Although this divergence is not problematic
on its own, for there to be a finite boundary on which the dual CFT will yield values for physical
quantities that do not diverge, we impose a cutoff r0 and restrict the space of interest to r ≤ r0. In
the dual CFT, this corresponds to imposing a UV cutoff where there is a minimal distance
between field values of a, the lattice spacing (cf. Susskind and Witten 1998). We can then think
21
of the CFT as living on the boundary of AdS3 where r=r0. This makes the 1+1-dimensional
spacetime for the CFT a cylinder (t, θ) with radius r0.
Ryu and Takayanagi consider the static case where the CFT lies on a single time slice t.
Figure 8: Static Case
As mentioned, Hubeny, Rangamani, and Takayanagi (2007) later extended this argument to
more general regions to give a covariant result. To give the main idea of how this is established, I
will focus on the static case and closely follow the 2006 discussion. Take a particular time-slice
of the cylinder and divide it into a region A and its complement, such that A corresponds to 0 ≤ θ
≤ %ABC
, where l is the length of A and L is the length of the total boundary. The minimal surface γA
then will be the geodesic with fixed t that connects the points θ = 0 and θ = %ABC
. This will be a
geodesic running through the AdS3 spacetime.
22
Ryu and Takayangi compute the length of the geodesic from the metric as 1 +
2𝑠𝑖𝑛ℎ%𝜌D𝑠𝑖𝑛%ABC
. And then using this for the area of 𝛾!, they use the proposed area law (6.1) to
get an expression for 𝑆(𝜌!). The neat thing is that the result given by the area law is confirmed
by independent work on the entanglement entropy of many body 1+1-dimensional CFTs. As Ryu
and Takayanagi note, Calabrese and Cardy (2004) showed (generalizing results of Hozheny et.
al. 1994) that for 1+1-dimensional CFTs, the entanglement entropy of a quantum many-body
system (with periodic boundary conditions) is given by:
(6.3) 𝑆(𝜌!) =EF𝑙𝑜𝑔 W C
A'𝑠𝑖𝑛 XAB
CYZ,
where again L is the length of the total system, l is the length of A, a is the lattice spacing, and c
is the CFT’s central charge. Recalling that our CFT has central charge c = 3R/2GN, we then
recover:
(6.4) 𝑆(𝜌!) =EF𝑙𝑜𝑔(𝑒G1𝑠𝑖𝑛 AB
C),
assuming 𝑒G1 ≫ 1.
The form of argument Ryu and Takayanagi use may be summarized as follows. Using the
AdS3 metric, we can compute the area of a minimal surface connecting the edges of region A
through the bulk. If we then assume the area law, this allows us to calculate a certain formula for
the entanglement entropy 𝑆(𝜌!) in the language of conformal field theory. This turns out to be
the correct formula for 𝑆(𝜌!) within a 1+1-dimensional CFT, given independent results. This
thus confirms the area law. Ryu and Takayanagi develop similar arguments for more
complicated setups in higher dimensions (2006a,b).
So we get confirmation of Ryu and Takayanagi’s conjecture of an area law, but this does
raise the question of why such an area law obtains. What grounds the connection between 𝑆(𝜌!)
and the area of 𝛾!? Discussions of Ryu and Takayanagi’s paper often take their result to support
23
the emergence of spacetime from an underlying quantum theory without gravitational degrees of
freedom, but although their arguments certainly confirm an entanglement-distance link, they
don’t provide the explanation of why this link should hold, and as such cannot support Option
(1) over its three rivals. Here I would suggest it is helpful if we think about the Bekenstein-
Hawking law, which inspired Ryu and Takayanagi’s conjecture. Bombelli et. al. (1986) develop
an illuminating physical argument that provides an explanation of why the Bekenstein-Hawking
relationship holds. As it works by explicating Bekenstein-Hawking entropy as a form of
entanglement entropy, it can help us to better understand the metaphysical implications of the
Ryu-Takayanagi paper, which essentially takes the Bekenstein-Hawking result and generalizes it
outside of the black hole context.13
The core idea introduced in Sorkin (1983) and developed in Bombelli et. al. (1986) is to
treat the source of black hole entropy as related to its entanglement entropy, and find the
entanglement entropy of the black hole by considering the entanglement entropy of the region
outside it.14 This is illustrated using a simple model, where the states of the total region consist of
the states of a massless scalar field in its vacuum state. To calculate the entanglement entropy,
we can represent the field as a lattice of harmonic oscillators with density 1 ℓF] . This allows us to
represent the entanglement entropy as a sum over eigenvalues 𝜆5 for an operator Λ, using the
previously stated relation:
13 It should be noted that arguments based on the claim that black hole entropy is entanglement entropy do not provide the only path to explaining the Bekenstein-Hawking formula. For example, one also finds arguments that one can arrive at the relationship just by counting states. To see how this is done in the string theory context, see e.g. Strominger and Vafa (1996). However, the form of argument I will describe and closely related arguments presented e.g. by Srednicki (1993) are the most salient if one wants an explanation that can be carried over to the Ryu-Takayanagi area law which concerns entanglement entropy. 14 Sorkin introduced the idea of entanglement entropy in this 1983 paper.
24
(6.5) 𝑆(𝜌) = ∑ 𝜆5𝑙𝑜𝑔#>+5 .
This operator Λ encodes the correlations between points in the lattice and importantly depends on
a division of points in the lattice into those internal and external to the black hole. See Bombelli
et. al. (1986) for the details and Sorkin (1983) for an overview, but the core idea is that assuming
a finite number of points in the lattice, the main contribution to the entanglement entropy will
come from the values of Λ closer to the horizon (cf. Carlip 2009). And so, given how Λ is
constructed, “the leading term in S will be proportional to A/ℓ2 where A is the area of the surface
(“horizon”) separating Hint from Hext” (Sorkin 1983, p. 3).15 The entropy of a black hole thus
scales with the area of its event horizon. This is because the sum in (6.5) is dominated by terms
describing the states of the field near the boundary, and thus the size of the boundary between the
regions inside and outside of the black hole is imposing a constraint on the leading contribution
to 𝑆(𝜌)H1).
We can see why this is by considering that any physically acceptable state of the field
will be a Hadamard state.16 As noted in Unruh and Wald (2017, p. 2), the leading order behavior
for Hadamard states Ψ of a free scalar field 𝜙 at two points x1 and x2 is:
(6.6) ⟨Ψ|𝜙(𝑥#)𝜙(𝑥%)|Ψ⟩~I(H&,H))
(%A))K(H&,H))
This is the two-point function of the field, where 𝑈(𝑥#, 𝑥%) is some smooth function and
𝜎(𝑥#, 𝑥%) is the squared geodesic distance between the two points. From (6.6), it is easily seen
that the two-point function diverges as x1 and x2 approach one another. And so, as the operator Λ
15 Hint and Hext are the two spacelike hypersurfaces we are considering inside and outside of the black hole. 16 Wald (1994, Chapters 2-3) argues that the requirement that states be Hadamard ensures that the stress-energy tensor is defined.
25
encodes the correlations between points inside and outside of the event horizon, the largest
contributions to (6.5) will come from those right at the event horizon.
Bombelli et. al.’s derivation of an area law for the entanglement entropy of a black hole,
at least the contribution to this entropy given by a massless scalar field, justifies the posited area
law of Bekenstein and Hawking. And so we can use this justification to ask about the
justification for the area law of Ryu and Takayanagi.
7. No Support for Emergence
It is clear from the above discussion of black hole entropy that there is no antecedent reason to
view the area of the event horizon as constructed out of or emerging from the entanglement of
the reduced quantum state 𝜌"0. The most natural way to interpret the argument is that the
horizon area is providing a constraint on the black hole entropy. It is not emerging from the
entropy.17 Insofar as the Ryu-Takayanagi conjecture is providing a generalization of the black
hole area law, in that case too, there doesn’t seem to be any reason to view the area of the
minimal surface 𝛾! as constructed out of the entanglement entropy. It is more natural again to
view the area of the minimal surface as providing a constraint on the entanglement entropy. And
so, the burden of proof is on one who wants to interpret the area law of Ryu and Takayanagi in a
very different way metaphysically from the area law it was aimed at generalizing. This point
carries over to the work following Ryu and Takayanagi (e.g. Hubeny, Rangamani, and
Takayanagi 2007, Bao et. al. 2019, and so on). It is worth noting that Ryu and Takayanagi do not
17 This is the most natural interpretation of ‘t Hooft’s (1993) holographic proposal for black hole entropy as well, as he argues that the black hole entropy is maximal when it reaches 𝑆L'H =
#.𝐴.
“[The entropy] is saturated when one black hole has the largest possible size that still fits inside our area” (p. 5).
26
speculate about metaphysics in their original paper. Moreover, in a longer work (2006b) that
followed it, expanding on its implications, they present their results not as motivating the
emergence of spacetime but rather in an instrumental way: since it is often mathematically very
difficult to compute the entanglement entropy from the quantum field theory side of things, one
can make use of this proposed area law to get a good approximation of the entanglement entropy
(2006b, pp. 2-3).
One might argue that although the Ryu-Takayanagi conjecture was inspired by the
Sorkin-Bombelli explanation of the area law of Bekenstein and Hawking, and although there are
important analogies between black hole entropy and entanglement entropy on a CFT boundary,
this does not entail that there is an absolute alignment between the two cases.18 Although in the
case of the Bekenstein-Hawking law, facts about spatiotemporal distances do explain the
entanglement entropy, one might argue that in the case of the AdS/CFT correspondence, facts
about entanglement entropy are fundamental and instead explain the facts about spatiotemporal
distance. This is a coherent possibility. However, what I am trying to argue is that a more natural
attitude is to view the Ryu-Takayanagi result as supporting the generalization of the Sorkin-
Bombelli framework outside of the context it was initially intended to describe. And thus that in
general, entanglement entropy is constrained by interface (event horizon or minimal surface)
area. Interface area doesn’t emerge from entanglement entropy in either case.
18 There is one clear disanalogy between the cases that is worth mentioning. This is that the area that appears in the Bekenstein-Hawking relation is the area of the boundary between the two subsystems (interior and exterior of the black hole’s event horizon), but the area that appears in the Ryu-Takayanagi relation is not the area of the boundary between the two subsystems (A and its complement). In the latter case, the area in question is the area of the minimal surface through the bulk that ends on the boundary between A and its complement. This disanalogy, however, does not undermine the above argument, as the boundary between A and its complement itself plays a role in constraining the minimal surface area.
27
To make the case for Option (1), one needs to point to arguments in which entanglement
entropies are plausibly being used to explain metrical features, without thereby assuming them.
One may immediately think of the influential paper by Jacobson (1995), which derives the
Einstein Field Equation from facts about entanglement entropy. But Jacobson himself relies on
the Bekenstein-Hawking relationship (and the Sorkin-Bombelli explanation of it) in his
argument. So this doesn’t give us what we are looking for. Work of Padmanabhan (2010a,
2010b) comes closer, as it attempts to provide an explanation of the spacetime metric using a
more basic statistical mechanical framework for understanding facts about entanglement entropy.
Padmanabhan explicitly frames his work as a part of a project in emergent gravity:
In this paradigm, one considers spacetime (described by the metric, curvature etc.) as a
physical system analogous to a gas or a fluid (described by density, velocity etc.). The
fact that either physical system (spacetime or gas) exhibits thermal phenomena shows
there must exist microstructure in either system… We do not yet know what are the
correct microscopic degrees of freedom of the spacetime, but the horizon
thermodynamics provides a clue… (2010b, p. 3)
Padmanabhan (2010a) shows how one can use the equipartition law ∆𝐸 = (1 2] )(∆𝑛)𝑘"𝑇 to
derive the existence of these fundamental microscopic degrees of freedom and their relationship
to the spacetime metric such that:
(7.1) ∆𝑛 = ∆!B2) ,
where lP is the Planck length. The idea seems to be that the facts about entanglement entropy
motivate the postulation of these fundamental degrees of freedom which in turn ground the
structure of gravity and emergent spacetime. This is an intriguing possibility, however at this
stage, it is worth noting, given we don’t have any idea what these microscopic degrees of
28
freedom are, or a strong motivation for believing in them, how much more speculative these
arguments are than the arguments we saw above that show how facts about the entanglement
between components of quantum systems are constrained by facts about the interface surface
between these components. Then again, as Carlip (p.c.) points out, the latter kind of arguments
have had a “big head start.”
Let’s finally return to the case for area laws outside of the AdS/CFT context, the
argument we find in the results summarized in Eisert et. al. (2010) and followed up on by e.g.
Cao et. al. (2017). This route into the entanglement-distance link also fails to provide support for
the view that the facts about spatiotemporal distance emerge from facts about entanglement
entropy. As we saw, the way area laws were derived for quantum many body systems relied on
an initial assumption of local interactions. The idea is that when influences are only able to act
locally, then the limits on correlation and hence, entanglement will be restricted by the region’s
surface area. In this case again, there doesn’t seem to be support for the emergence hypothesis.
Again, what seems supported, indeed presupposed, by the whole discussion is that the area of the
boundary is constraining the entanglement of the two component regions, (for Eisert et. al., these
are I and its complement), by constraining the quantity of direct interactions. It is certainly much
more exciting and radical to view the entanglement-distance link as resulting from a fact about
emergence – that the spatiotemporal manifold is not fundamental, but ultimately results from
deeper, quantum information theoretic facts about quantum entanglement. But the way these
results are motivated does not support this radical view. In the framework in which the results
are articulated, the spatiotemporal facts are fundamental. They then constrain facts about
interactions, which then in turn constrain the facts about entanglement entropy.
29
8. Conclusion
What I have hoped to show is that there is strong support both from within and without the
AdS/CFT context for the existence of an important link between entanglement entropy and
spatiotemporal distance. However, these results do not lend obvious support for the speculation
that the dynamical spacetime of general relativity is emergent from facts about quantum
entanglement, at least this is not supported by work to date. One has to interpret results like that
of Ryu and Takayanagi in a way that departs significantly from the intuitions that make them
comprehensible to have them support the claim that spacetime emerges from the facts of
quantum entanglement.
This isn’t to say that one cannot use the results of Ryu and Takayanagi and the others to
support the claim that the metric emerges from facts about quantum entanglement. In a recent
book, Carroll suggests we do just that. He says:
…following our reverse-engineering philosophy, we can define the “area” of a collection
of degrees of freedom to be proportional to its entanglement entropy. In fact, we can
assert this for every possible subset of degrees of freedom, assigning areas to every
surface we can imagine drawing within our network… If the degrees of freedom are
highly entangled, we define them to be nearby … A metric on space has emerged from
the entanglement structure of the quantum state. (2019, p. 284)
Of course this is a move one can make, and certainly the attendant emergence hypothesis is one
we should keep on the table, especially as it seems supported by other routes into developing a
quantum theory of gravity (cf. Wüthrich 2017). However, the goal of this paper has been to make
clear that this is not what area laws most directly support, when we pay attention to how they
have been typically justified in physics.
30
Work Cited
Audenart, K., J. Eisert, M.B. Plenio, and R.F. Werner. 2002. Entanglement Properties of the
Harmonic Chain. Physical Review A. 042327.
Balasubramanian, Borun, D. Chowdhury, Bartlomiej Czech, Jan de Boer, and Michal Heller.
2014. A Hole-ographic Spacetime. Physical Review D. 89: 086004.
Bao, Ning, ChunJun Cao, Sebastian Fischetti, and Cindy Keeler. 2019. Towards Bulk Metric
Reconstruction from Extremal Area Variations. Classical and Quantum Gravity. 36(18).
Bekenstein, Jacob D. 1973. Black Hole Entropy. Physical Review D. 7(8): 2333.
Bombelli, Luca, Rabinder K. Koul, Joohan Lee, and Rafael D. Sorkin. 1986. Quantum Source of
Entropy for Black Holes. Physical Review D. 34(2): 373-383.
Butterfield, Jeremy. forthcoming. On Dualities and Equivalences Between Physical Theories.
Philosophy Beyond Spacetime. N. Huggett, B. Le Bihan, and C. Wüthrich, eds. Oxford: Oxford
University Press.
Cao, ChunJun, Sean M. Carroll, and Spyridon Michalakis. 2017. Space from Hilbert Space:
Recovering Geometry from Bulk Entanglement. Physical Review D. 95(2): 024031.
Calabrese, Pasquale and John Cardy. 2004. Entanglement Entropy and Quantum Field Theory.
Journal of Statistical Mechanics: Theory and Experiment. P06002.
Carlip, Steven. 2009. Black Hole Thermodynamics and Statistical Mechanics. Physics of Black
Holes. E. Papantonopoulos, ed. Lecture Notes in Physics. 769. Berlin: Springer.
Carlip, Steven. 2012. Challenges for Emergent Gravity. Studies in History and Philosophy of
Modern Physics. 46(1): 200-208.
31
Carroll, Sean. 2019. Something Deeply Hidden: Quantum Worlds and the Emergence of
Spacetime. Dutton.
Crowther, Karen. 2014. Appearing Out of Nowhere: The Emergence of Spacetime in Quantum
Gravity. PhD Thesis. University of Sydney.
De Haro, Sebastian. 2017. Dualities and Emergent Gravity: Gauge/Gravity Duality. Studies in
History and Philosophy of Modern Physics. 59: 109-125.
De Haro, Sebastian. 2020. Spacetime and Physical Equivalence. Beyond Spacetime: The
Foundations of Quantum Gravity. N. Huggett, K. Matsubara, and C. Wüthrich, eds. Cambridge:
Cambridge University Press.
Dieks, Dennis, Jeroen van Dongen, and Sebastian de Haro. 2015. Emergence in Holographic
Scenarios for Gravity. Studies in History and Philosophy of Modern Physics. 52: 203-216.
Eisert, J., M. Cramer, and M.B. Plenio. 2010. Area Laws for the Entanglement Entropy. Reviews
of Modern Physics. 82: 277.
Harlow, Daniel. 2020. What Black Holes Have Taught Us about Quantum Gravity. Beyond
Spacetime: The Foundations of Quantum Gravity. N. Huggett, K. Matsubara, and C. Wüthrich,
eds. Cambridge: Cambridge University Press, 105-114.
Hawking, S.W. 1975. Particle Creation By Black Holes. Communications in Mathematical
Physics. 43: 199-220.
Headrick, Matthew, Robert C. Myers, and Jason Wien. 2014. Holographic Holes and Differential
Entropy. Journal of High Energy Physics. 149.
Holzhey, Christoph, Finn Larsen, and Frank Wilczek. 1994. Geometric and Renormalized
Entropy in Conformal Field Theory. Nuclear Physics B. 424(3): 443-467.
32
‘t Hooft, G. 1993. Dimensional Reduction in Quantum Gravity. Salamfestscrhift. A. Ali, J. Ellis,
and S. Randjbar-Daemi, eds. Singapore: World Scientific.
Horowitz, Gary. 2005. Spacetime in String Theory. New Journal of Physics. 7: 201.
Hubeny, Veronika. 2014. Covariant Residual Entropy. Journal of High Energy Physics. 1-35.
Hubeny, Veronika, Mukund Rangamani, and Tadashi Takayanagi. 2007. A Covariant
Holographic Entanglement Entropy Proposal. Journal of High Energy Physics.
Huggett, Nick and Christian Wüthrich. 2013. Emergent Spacetime and Empirical (in)Coherence.
Studies in History and Philosophy of Modern Physics. 44(3): 276-285.
Huggett, Nick and Christian Wüthrich. forthcoming. Out of Nowhere. Oxford: Oxford University
Press.
Jacobson, Ted. 1995. Thermodynamics of Spacetime: The Einstein Equation of State. Physical
Review Letters. 75(7): 1260-1263.
Jaksland, Rasmus. forthcoming. Entanglement as the World-making Relation. Synthese.
Maldacena, Juan. 1997. The Large N Limit of Superconformal Field Theories and Supergravity.
Journal of High Energy Physics. 9711200.
Maldacena, Juan. 2003. Eternal Black Holes in Anti-de Sitter. Journal of High Energy Physics.
Myers, Robert C., Junjie Rao, and Sotaro Sugishita. 2014. Holographic Holes in Higher
Dimensions. Journal of High Energy Physics. 44.
Nielsen, Michael A. and Isaac L. Chuang. 2016. Quantum Computation and Quantum
Information. Cambridge: Cambridge University Press.
Oriti, Daniele. forthcoming. Levels of Spacetime Emergence in Quantum Gravity. Philosophy
Beyond Spacetime. N. Huggett, B. Le Bihan, and C. Wüthrich, eds. Oxford: Oxford University
Press.
33
Padmanabhan, T. 2010a. Surface Density of Spacetime Degrees of Freedom from Equipartition
Law in Theories of Gravity. Physical Review D. 81: 1-12.
Padmanabhan, T. 2010b. Finite Entanglement from the Zero-Point Area of Spacetime. Physical
Review D. 82:1-6.
Preskill, John. 1998. Lecture Notes on Quantum Information and Computation. Online at:
http://www.theory.caltech.edu/people/preskill/ph229/notes/book.ps.
Rangamani, Mukund and Tadashi Takayanagi. 2017. Holographic Entanglement Entropy.
Chaim: Springer.
Read, James. 2016. The Interpretation of String-Theoretic Dualities. Foundations of Physics. 46:
209-235.
Rickles, Dean. 2013. AdS/CFT Duality and the Emergence of Spacetime. Studies in History and
Philosophy of Modern Physics. 44(3): 312-320.
Ryu, Shinsei and Tadashi Takayanagi. 2006a. Holographic Derivation of Entanglement Entropy
from the anti-de Sitter Space/Conformal Field Theory Correspondence. Physical Review Letters.
96: 181602.
Ryu, Shinsei and Tadashi Takayanagi. 2006b. Aspects of Holographic Entanglement Entropy.
Journal of High Energy Physics.
Sorkin, Rafael. 1983. On the Entropy of the Vacuum Outside a Horizon. Tenth International
Conference on General Relativity and Gravitation Contributed Papers Vol. II. B. Bertolli, F. de
Felice, and A. Pascolini, eds. Rome: Consiglio Nazionale Delle Ricerche. 734-736.
Srednicki, Mark. 1993. Entropy and Area. Physical Review Letters. 71(5): 666-669.
Strominger, Andrew and Cumrun Vafa. 1996. Microscopic Origin of the Bekenstein-Hawking
Entropy. Physics Letters B. 379: 99-104.
34
Susskind, Leonard and Edward Witten. 1998. The Holographic Bound in Anti-de Sitter Space.
hep-th/9805114.
Teh, Nicholas J. 2013. Holography and Emergence. Studies in History and Philosophy of
Modern Physics. 44(3): 300-311.
Van Raamsdonk, Mark. 2010. Building Up Spacetime With Quantum Entanglement. General
Relativity and Gravitation. 42: 2323-2329.
Wald, Robert. 1994. Quantum Field Theory in Curved Spacetime and Black Hole
Thermodynamics. Chicago: University of Chicago Press.
Witten, Edward. 1998. Anti-de Sitter Space and Holography. Advances in Theoretical and
Mathematical Physics. 2: 253-291.
Wüthrich, Christian. 2017. Raiders of the Lost Spacetime. Toward a Theory of Spacetime Theories. D. Lehmkuhl, ed. New York: Birk